Permanent magnet rotor

Description

[0001] The present invention relates to a permanent magnet rotor for an electrical machine, and more particularly relates to a generator rotor that is especially suitable for a wind turbine.

BACKGROUND ART

[0002] Electrical machines, such as motors and generators having a rotor with permanent magnets are known. They are generally deemed to be reliable and require less maintenance than other generator topologies.

[0003] Modern wind turbines are commonly used to supply electricity into the electrical grid. Wind turbines of this kind generally comprise a rotor with a rotor hub and a plurality of blades. The rotor is set into rotation under the influence of the wind on the blades. The rotation of the rotor shaft either directly drives the generator rotor ("directly driven") or through the use of a gearbox. Particularly for offshore wind turbines, direct drive systems employing permanent magnets are usually chosen.

[0004] Such a direct drive wind turbine generator may have e.g. a diameter of 6 - 8 meters and a length of e.g. 2 - 3 meters. Hundreds of magnets may need to be attached, e.g. by screwing or gluing to the circumference of the rotor. It will be clear that this manufacturing process can be cumbersome.

[0005] Furthermore, if one or more of the magnets is damaged and needs to be replaced, the access to these magnets can be complicated (especially with large size generators), such that maintenance can become very expensive.

[0006] This size and type of generator however is not limited to offshore applications, and not even to the field of wind turbines only. Generators of considerable dimensions that may suffer from the same problems and/or have the same complications may also be found e.g. in steam turbines and water turbines. Also relatively large permanent magnet motors may have the same or similar problems.

[0007] Cooling of the components is generally an important requirement in electrical machines. A cooling air flow may be established by the rotation of the rotor. In some implementations, an additional cooling air flow may be provided by a dedicated fan. Furthermore, in some implementations a liquid cooling circuit may be provided. Incorporation of a cooling circuit may further complicate the assembly and manufacture of large permanent magnet generators. A plurality of radial cooling holes may need to be drilled. These radial holes may complicate manufacture and assembly and will generally not lead to homogeneous cooling.

[0008] DE 10 2005 042 543 discloses a machine with a stator with a coil system, and pole segments arranged on a magnet wheel, where the pole segments exhibit permanent magnets. The pole segments are provided within an area of pole shoes, where each shoe is provided with recesses.

SUMMARY OF THE INVENTION

[0009] The present invention provides a permanent magnet rotor according to claim 1. Various embodiments are set out in the dependent claims.

[0010] The present invention provides a permanent magnet rotor and comprising a rotor rim and a plurality of permanent magnet modules arranged on the outer or inner circumference of the rotor rim. The permanent magnet modules extend generally along an axial direction and are of substantially constant axial-cross section, and comprise a base adapted to be fixed to the rim of the generator rotor, one or more permanent magnets, and one or more pole pieces. The permanent magnet modules comprise an axial cooling channel extending substantially along the length of the modules.

[0011] In this aspect of the invention, a permanent magnet rotor is provided for which the assembly and maintenance is facilitated. Both for repair and manufacture, modules of magnets can be relatively easily inserted in place and removed. Additionally, the cooling channel integrated in the permanent magnet module is able to provide suitable cooling, without complicating the assembly of the generator rotor.

[0012] Herein, axial cross-section may be defined as the cross-section with a plane that is perpendicular to the rotational axis of the rotor. An axial direction may be defined as a direction coinciding with the rotational axis of the rotor or parallel thereto.

[0013] In some embodiments, the axial cooling channel may be delimited by one or more of the magnets. The cooling may thus more effectively cool the magnets. Additionally, the cooling channel may be formed e.g. by punching or laser cutting at the same time that the slots / holes for the magnets are formed.

[0014] According to the invention, the permanent magnets have a circumferential magnetic orientation and are substantially rectangular in axial cross-section and each of the permanent magnets is inclined with respect to the central radial plane of the module and/or with respect to the radial plane of the magnet. The inclined magnets may lead to beneficial power and torque characteristics as their magnetic flux may be more concentrated. In some embodiments, the magnets may be arranged perpendicular to the central radial plane of the magnets, i.e. in this case they are "tangentially" arranged.

[0015] In some embodiments, one or more of the permanent magnet modules may comprise a first and a second axial row of permanent magnets and a central cooling channel arranged between said first and second rows. Such a central cooling channel may be formed as an orifice extending axially through the permanent magnet modules. The axial rows of magnets may include a single magnet, or two or more magnets axially positioned behind each other.

[0016] In other embodiments, one cooling channel may be incorporated at the foot (i.e. inner end) of each of the (rows of) magnets, and at least one cooling channel may be incorporated at the top (i.e. outer end) of each of the (rows of) magnets.

[0017] In yet further embodiments, a cooling channel may be arranged at one or more of the four corners of one or more of the (rows of) magnets. If a plurality of cooling channels is provided in each of the modules, the cooling channels may be smaller.

[0018] In some embodiments, each of the permanent magnet modules may comprise two axial rows of magnets. In preferred embodiments, all the modules may be substantially identical. The assembly of the generator rotor may thus be simplified. In alternative embodiments, modules with a single permanent magnet may be used. Not all modules may necessarily be identical in this configuration.

[0019] According to the invention, the base and pole pieces of the permanent magnet modules are integrally formed and the magnets are embedded in the permanent magnet modules. If the base and pole pieces are integrally formed (i.e. they form a monolithic piece) in axial cross-section, the manufacturing tolerances for the modules may be reduced. In these embodiments, the holes for inserting the permanent magnets and the cooling channels at the foot and at the top of the magnets may be formed during the same punching or laser cutting process. In this case, the cooling channels may be formed as the space of the holes not occupied by the permanent magnets.

[0020] In other embodiments, the magnets may be glued and/or screwed on top of the base or pole pieces.

[0021] In some embodiments, the rotor may comprise a plurality of anchors for fixing the permanent magnet modules to the rotor rim, wherein the permanent magnet modules comprise a base having a bottom surface adapted to be fit to the inner or outer circumference of the rotor rim, and two axially extending side surfaces, and the two side surfaces of the base of the permanent magnet modules each comprise an axially extending groove, and wherein the anchors have a shape that fits in axially extending grooves of neighbouring permanent magnet modules. Optionally, these anchors may be substantially T-shaped.

[0022] In these embodiments, a particularly easy way of installing the modules on the rotor rim is provided. The anchors may first be loosely attached to the rotor rim. After placement of the module, the anchor may be tightened and may engage with the base of the module.

[0023] In other embodiments, each of the permanent magnet modules may comprise a plurality of radial holes, and the permanent magnet modules may be fixed to the rotor rim by a plurality of bolts inserted in the radial holes.

[0024] In yet a further aspect, the disclosure provides a wind turbine comprising a generator having a rotor substantially as hereinbefore described. In some implementations, the wind turbine may be a direct drive wind turbine. In particular, the wind turbine may be an offshore direct drive wind turbine.

BRIEF DESCRIPTION OF THE DRAWINGS

[0025] Particular embodiments of the present invention will be described in the following by way of non-limiting examples, with reference to the appended drawings, in which:

Figure 1 illustrates an axial cross-section of a permanent magnet module in accordance with a first embodiment of the present invention;

Figures 2a - 2b schematically illustrate a rotor in accordance with further embodiments of the present invention;

Figures 3a and 3b schematically illustrate a rotor in accordance with a further example, not part of the claimed invention;

Figures 4a - 4c schematically illustrate a rotor in accordance with yet further example, not part of the claimed invention.

DETAILED DESCRIPTION OF EMBODIMENTS

[0026] Figure 1 illustrates an axial cross-section of a permanent magnet module in accordance with a first embodiment of the present invention. Permanent magnet module 10 comprises a base 13, a first permanent magnet 11 and a second permanent magnet 12. The axial rows of magnets may be a single magnet, or a plurality of magnets axially positioned behind each other.

[0027] The North and South of the permanent magnets may be as indicated in figure 1. The magnets have a circumferential orientation (also sometimes referred to as "transversal" or "tangential" orientation), i.e. the North and South of each of the magnets are arranged in the rotor next to each other in a circumferential (or "tangential") direction.

[0028] The magnets may be inclined towards a central radial plane 2 of the module. The magnets do not extend along the local radial planes 4 and 6 (the radial planes passing through the center of the magnets), as illustrated in figure 1. The magnetic flux lines from the North of the second magnet 12 to the South of the fist magnet 11 will be substantially straight, i.e. horizontal. The two magnets together may form a single pole, and the magnetic flux lines from the North of the first magnet to the South on the second magnet will enclose a winding arranged on the stator (not shown). Pole pieces 14a and 14b act as flux concentrators.

[0029] The permanent magnet module may be of substantially constant cross-section and may comprise a stack of metal sheets. The metal sheets of the stack may be welded stuck to each other, or may be joined e.g. by adhesives. Such a laminated structure may reduce or avoid eddy currents.

[0030] The metal sheets may be formed by punching or e.g. laser cutting and may be glued together. Rectangular through-holes may be formed in the metal sheets so as to embed the rectangular permanent magnets. These holes may also be formed e.g. by punching or by laser cutting. In alternative embodiments, instead of a stack of metal sheets, an integral piece could be used. Embedding the magnets in this way reduces the part count and as a result of the reduction of components that are to be assembled, tolerances may automatically decrease.

[0031] In this embodiment, an axially extending cooling channel 15a is provided at the foot (i.e. inner end) of the first magnet 11. Another cooling channel 15b is provided at the top (i.e. outer end) of the first magnet. Similar cooling channels 17a and 17b are provided at the foot and top of the second magnet respectively. Cooling of the modules (and generator in general) may thus be provided in a particularly simple manner.

[0032] The magnets may be securely fixed using suitable adhesive. At both the front and the rear end, the magnets may be sealed from the outside using e.g. end plates and/or epoxy resin.

[0033] The base 13 has a top with a substantially isosceles triangular cross-section with the permanent magnets arranged along the sides of the triangle. The bottom 24 of the base may be adapted to fit on the inner or outer circumference of the rotor rim. The bottom 24 of the base may thus be slightly curved.

[0034] A weight saving recess 18 may be provided at the bottom. The side surfaces of the base may comprise grooves. The base 13 may comprise legs 29 forming the lower end of the grooves. Suitably shaped anchors may be used for fixing the permanent magnet modules to the rotor rim. The anchors may be of such shape that they engage with the surfaces of the grooves 16 (and legs 29) when fixed. T-shaped anchors may sit substantially exactly in the grooves 16.

[0035] To assemble the rotor, the anchors may be loosely attached at the circumference of the rotor rim. Then, the permanent magnet modules 10 may be inserted and slid between two neighbouring anchors. Then, to fix the magnet modules in place, the bolts of the anchors may be tightened, so that the anchors press a portion of the base against the circumference of the rotor rim.

[0036] In this aspect, a permanent magnet rotor is provided for which the assembly and maintenance is facilitated. Both for repair and manufacture, modules of magnets can be relatively easily inserted and removed. Friction between the magnets and rotor rim during installation and/or maintenance may be avoided.

[0037] The base 13 and pole pieces may e.g. be made from steel or another magnetically conducting material. The permanent magnets may be made e.g. from AINiCo steel (Aluminium-Nickel-Cobalt), rare earth magnetic materials such as neodymium (NdFeB), or samarium-cobalt, but may also be made from e.g. ceramic materials.

[0038] Figures 2a and 2b illustrate another embodiment in axial cross-section and in radial cross-section respectively.

[0039] Figure 2a illustrates two permanent magnet modules installed on the rotor rim next to each other. Each of the modules 10 and 10' may comprise a first magnet 11 (or first axial row of magnets) and a second magnet 12 (or second axial row of magnets) which are rectangular and are inclined with respect to the local radial planes of the magnets.

[0040] The permanent magnet modules have a circumferential magnetic orientation. It may be seen that the magnetization of the magnets of one module is the opposite of the magnetization of the magnets of the neighbouring module. Pole pieces 14a and 14b may act as flux concentrators.

[0041] In alternative embodiments, the two neighbouring modules could be formed as a single module.

[0042] Also illustrated in figure 2a are the stator 20 and the air gap 25 between rotor and stator. In this embodiment, the stator substantially surrounds the rotor. In other implementations, the rotor may surround the stator.

[0043] The permanent magnet modules may comprise a central cooling channel 19. Further, smaller cooling channels 15a, 15b, 15c and 15d may be provided in the four corners of the rectangular magnets. The magnets may be embedded in the permanent magnet modules. To form the cooling channels in the corners of the permanent magnets, the axial holes in which the permanent magnets may be inserted may incorporate rounded corners. The holes may be formed by e.g. punching or laser cutting. The space not occupied by the magnets after their insertion may serve as cooling channel(s).

[0044] T-shaped anchors 30 may be used to attach the modules to the outer circumference of the rotor rim 32. The two sideways extending anchoring portions of the T-shaped anchor fit in a corresponding groove 16 of the permanent magnet modules and thus lock the legs 29 of the permanent magnet module in place.

[0045] Since the grooves in the side surfaces of the modules are substantially larger than the corresponding side portions of the anchors, a space remains between two modules. This space may serve for cooling.

[0046] The attachment of the permanent magnet modules to the rotor rim may further be seen in figure 2b, which represents a radial cross-section along line A-A indicated in figure 2a.

[0047] In the embodiments illustrated in figures 1 and 2, the pairs of (rows of) embedded magnets of the modules are arranged as an inverted "V". This disposition of magnets may have advantages during assembly and installation. Neighbouring modules repel each other, which may facilitate assembly. Additionally, it may be easier to magnetize the permanent magnets.

[0048] Figures 3a and 3b illustrate further examples, in which the permanent magnets are not embedded in the modules and this arrangement is not covered by the claims. Permanent magnet modules 10, 10' and 10" in this case comprise a base, magnet support side plates 51 and 52, and central magnet support structure 53, which acts as a flux concentrator. The central magnet support structure 53 may be regarded as composed of two pole pieces.

[0049] The pole pieces, base and central magnet support structure may be formed as a stack of metal sheets 60, 61, 62 etc. as illustrated in figure 3b. The stack of sheets may be glued together. In the implementation illustrated in figures 3a and 3b, the stack of metal sheets is further held together by rods 54 and 55 that exert a pressure on the stack of sheets.

[0050] The module may further comprise a bar 45 to which magnet support plates are attached, e.g. by brazing. The magnet support plates 51 and 52 may comprise ends 56 that are formed to retain magnets 11 and 12. The side support plates may be substantially flat and comprise upstanding end portion.

[0051] The central magnet support structure 53 may be shaped substantially as an inverted triangle in axial cross-section. The magnets 11 and 12 may be arranged along the sides of the central magnet support structure and may be attached to both the central support structure and to the side support plates by suitable adhesives. In its apex (i.e. at the bottom of the inverted triangle), the central support structure may comprise a shape adapted to retain the magnets, e.g. two lateral protrusions 57 that cooperate with the end portions of the side support plates to mechanically retain the magnets.

[0052] Also in this embodiment, the magnets may be substantially inclined providing the same advantages with respect to torque and power.

[0053] To mount the modules, a plurality of radial mounting holes is foreseen in the rotor rim and corresponding radial mounting holes are foreseen in the bar 45. After positioning of the module on the rotor rim, bolts 42 may be introduced in the radial mounting holes and fix the modules in place.

[0054] Figures 4a - 4c schematically illustrate yet further examples of permanent magnet rotors. Figure 4a illustrates an axial cross-section of a rotor rim with two permanent magnet modules. Figure 4b shows a radial cross-section along line A-A indicated in figure 4a. Figure 4c shows a radial cross-section along line B-B indicated in figure 4a.

[0055] The example of the generator rotor illustrated in figure 4a comprises a plurality of permanent magnet modules 10 and 10' attached to the rotor rim 32. The advantages related to the use of modules are also obtained in this example.

[0056] Each permanent magnet module may comprise a first magnet 11 and a second magnet 12 and a central cooling channel 19 located between the first and second magnet. The axial cooling channel incorporated in the modules is able to provide cooling without complicating the manufacture and assembly of the generator rotor.

[0057] The permanent magnets may be of generally rectangular cross-section and may be inclined towards a central radial plane (line B-B) of the permanent magnet module. The magnets may have a circumferential magnetic orientation as indicated in figure 4a. The circumferential magnetization and the inclination of the magnets provide beneficial power and torque characteristics to the generator.

[0058] The permanent magnet module may comprise a central magnet support 53 which acts as a flux concentrator with a cross-section that is substantially close to an inverted triangle, similar to the embodiment illustrated in figure 3a. At the top two vertices of the triangle, lateral hooks 79 may be incorporated in order to mechanically lock the permanent magnets in between the central magnet support structure 59 and the base 13 of the permanent magnet module.

[0059] The central magnet support structure 53 may comprise an axial hole 74 in which a rod 76 may be inserted. A plurality of radial holes, at different axial positions, may be drilled in the central magnet support structure. Rod 76 may comprise a number of transverse through-holes, such that when the rod is inserted, the transverse through-holes are lined up with the radial holes of the magnet support structure. Bolts 71 with nuts 72 may be inserted in these radial holes may extend into and beyond the transverse holes of rod 76, into an upper portion of the central magnet support structure 53. The permanent magnets may thus be clamped between base 13 and central magnet support structure 53. An alternative secure way of fixing the magnets in the module, which is not covered by the claims, may thus be established.

[0060] The base 13 may comprise, as shown in other embodiments, side surfaces with grooves 16. Anchors 30 with a shape that is substantially complementary to the shape of the groove may press the legs 29 of base 13 against the rotor rim and fix the permanent magnet module in place.

[0061] In the examples of figures 3 and 4, the pairs of (rows of) embedded magnets of the modules are arranged as a "V". This disposition of magnets in combination with the integrated cooling channels may reduce leakage of magnetic flux.

[0062] Inclination of the magnets with respect to the corresponding local radial plane may vary (radial plane passing through the center of the magnet). The angle of inclination with respect to the radial plane may be in the range of 0 - 90°, more particularly in the range of 10 ° - 50 °, in particularly between 10° and 40°.

[0063] The permanent magnet modules as illustrated herein may have a length that substantially corresponds to the axial length of the electrical machine, e.g. a generator or motor; each permanent magnet module thus spans substantially the entire length of the electrical machine. In other embodiments, the length of a module may be substantially half of the axial length of the electrical machine; two permanent magnet modules span the length of the electrical machine. In these cases, one module may be inserted from the front and one module may be inserted from the rear. Similarly, in some embodiments, the anchors may span the length of the electrical machine. In other embodiments, the anchors may be divided in various segments that together span the length of the electrical machine.

[0064] In most of the embodiments illustrated herein, T-shaped anchors were used to securely fix the base of the modules to the rotor rim. In other embodiments, other anchors may be used that have a different shape that is substantially complementary to the grooves formed in the side surfaces of the base.

[0065] Although only a number of particular embodiments of the invention have been disclosed herein, it will be understood by those skilled in the art that other alternative embodiments and/or uses of the invention and obvious modifications thereof are possible. Thus, the scope of the present invention should not be limited by particular embodiments, but should be determined only by a fair reading of the claims that follow.

Claims

1. A permanent magnet rotor comprising a rotor rim (32) and a plurality of permanent magnet modules (10, 10', 10") arranged on the outer or inner circumference of the rotor rim (32),
the permanent magnet modules (10, 10', 10") extending generally along an axial direction and being of substantially constant axial-cross section, and the permanent magnet modules comprising
a base (13) adapted to be fixed to the rim (32) of the generator rotor, one or more permanent magnets (11, 12), and one or more pole pieces (14a, 14b), wherein the base (13) and pole pieces (14a, 14b) of the permanent magnet modules (10, 10', 10") are integrally formed and the magnets (11, 12) are embedded in the permanent magnet modules (10, 10', 10"),
wherein each of the permanent magnets (11, 12) has a circumferential magnetic orientation and is substantially rectangular in axial cross-section and
wherein each of the permanent magnets (11, 12) is inclined with respect to the radial plane (4,6) passing through the center of the respective magnet (11, 12)
characterized in that
each of the permanent magnet modules (10, 10', 10") comprises an axial cooling channel (15a, 15b, 15c, 15d, 17a, 17b, 19) integrated in the respective permanent magnet module and extending substantially along the length of the modules (10, 10', 10").

2. A permanent magnet rotor according to claim 1, wherein the axial cooling channel (15a, 15b, 15c, 15d, 17a, 17b, 19) is delimited by one or more of the magnets (11, 12).

3. A permanent magnet rotor according to claim 1 or 2, wherein the permanent magnet modules (10, 10', 10") comprise a first and a second axial row of permanent magnets (11, 12) and a central cooling channel (19) arranged between said first and second rows (11, 12).

4. A permanent magnet rotor according to claim 3, wherein the central cooling channel (19) extends from an edge of the first row of magnets (11) to an edge of the second row of magnets (12).

5. A permanent magnet rotor according to any of claims 1 - 4, wherein one or more of the permanent magnet modules (10, 10', 10") comprise at least one cooling channel (15a, 15c, 15d, 17a, 19) at the foot of each of the magnets (11, 12), and/or at least one cooling channel (15b, 17b, 15a) at the top of each of the magnets (11, 12).

6. A permanent magnet rotor according to claim 5, wherein one or more of the permanent magnet modules (10, 10', 10") comprise a cooling channel (15a, 15b, 15c, 15d) at one or more of the four corners of one or more of the magnets (11, 12).

7. A permanent magnet rotor according to any of claims 1 - 6, wherein all the modules (10, 10', 10") are substantially identical.

8. A permanent magnet rotor according to any of claims 1 - 7, wherein the magnets (11, 12) are screwed to the modules (10, 10', 10").

9. A permanent magnet rotor according to any of claims 1 - 8, wherein the magnets (11, 12) are glued to the base (13) and/or pole pieces (14a, 14b).

10. A permanent magnet rotor according to any of claims 1 - 9, further comprising a plurality of anchors (30) for fixing the permanent magnet modules (10, 10', 10") to the rotor rim (32), wherein
the permanent magnet modules (10, 10', 10") comprise a base (13) having a bottom surface adapted to be fit to the inner or outer circumference of the rotor rim (32), and two axially extending side surfaces, and
the two side surfaces of the base (13) of the permanent magnet modules (10, 10', 10") each comprise an axially extending groove (16), and wherein
the anchors (30) have a shape that fits in axially extending grooves (16) of neighbouring permanent magnet modules (10, 10', 10").

11. A permanent magnet rotor according to claim 10, wherein the anchors (30) are substantially T-shaped.

12. A permanent magnet rotor according to any of claims 1 - 9, wherein each of the permanent magnet modules (10, 10', 10") comprises a plurality of radial holes, and wherein the permanent magnet modules (10, 10', 10") are fixed to the rotor rim (32) by a plurality of bolts (42, 71, 72) inserted in the radial holes.

13. A permanent magnet rotor according to any of claims 1 - 12, wherein the base (13) and pole pieces (14a, 14b) are formed by a stack of metal sheets (60, 61, 62).

14. Wind turbine comprising a generator having a generator rotor according to any of claims 1 - 13.

Ansprüche

1. Ein Dauermagnetrotor umfassend einen Rotorkranz (32) und eine Vielzahl von auf dem äußeren oder inneren Kreisumfang des Rotorkranzes (32) angeordneten Dauermagnetmodulen (10, 10', 10"),
wobei sich die Dauermagnetmodule (10, 10', 10") allgemein entlang einer axialen Richtung erstrecken und einen im Wesentlichen konstanten axialen Querschnitt haben, und wobei die Dauermagnetmodule folgendes umfassen
einen Basisteil (13), der angepasst ist, um am Kranz (32) des Generatorrotors befestigt zu werden, einen oder mehrere Dauermagnete (11, 12), und ein oder mehrere Polstücke (14a, 14b), wobei der Basisteil (13) und die Polstücke (14a, 14b) der Dauermagnetmodule (10, 10', 10") integral ausgebildet sind und die Magnete (11, 12) in den Dauermagnetmodulen (10, 10', 10") eingebettet sind,
wobei jeder Dauermagnet (11, 12) eine dem Kreisumfang entsprechende magnetische Ausrichtung hat und im axialen Querschnitt im Wesentlichen rechteckig ist und
wobei jeder Dauermagnet (11, 12) geneigt bezüglich der den Mittelpunkt des jeweiligen Magnets (11, 12) durchgehenden radialen Ebene (4,6) ist
dadurch gekennzeichnet, dass
jedes Dauermagnetmodul (10, 10', 10") einen axialen Kühlkanal (15a, 15b, 15c, 15d, 17a, 17b, 19) umfasst, der im jeweiligen Dauermagnetmodul integriert ist und sich im Wesentlichen entlang der Länge der Module (10, 10', 10") erstreckt.

2. Ein Dauermagnetrotor nach Anspruch 1, wobei der axiale Kühlkanal (15a, 15b, 15c, 15d, 17a, 17b, 19) durch einen oder mehrere Magnete (11, 12) begrenzt ist.

3. Ein Dauermagnetrotor nach Anspruch 1 oder 2, wobei die Dauermagnetmodule (10, 10', 10") eine erste und eine zweite axiale Reihe von Dauermagneten (11, 12) und einen mittleren Kühlkanal (19) umfassen, der zwischen der ersten und der zweiten Reihe (11, 12) angeordnet ist.

4. Ein Dauermagnetrotor nach Anspruch 3, wobei der mittlere Kühlkanal (19) sich von einer Kante der ersten Reihe von Magneten (11) bis zu einer Kante der zweiten Reihe von Magneten (12) erstreckt.

5. Ein Dauermagnetrotor nach einem der Ansprüche 1 - 4, wobei ein oder mehrere Dauermagnetmodule (10, 10', 10") mindestens einen Kühlkanal (15a, 15c, 15d, 17a, 19) am Fuß von jedem Magnet (11, 12) umfassen, und/oder mindestens einen Kühlkanal (15b, 17b, 15a) im oberen Teil von jedem Magnet (11, 12) umfassen.

6. Ein Dauermagnetrotor nach Anspruch 5, wobei ein oder mehrere Dauermagnetmodule (10, 10', 10") einen Kühlkanal (15a, 15b, 15c, 15d) an einer oder mehreren der vier Ecken von einem oder mehreren Magneten (11, 12) umfassen.

7. Ein Dauermagnetrotor nach einem der Ansprüche 1 - 6, wobei alle Module (10, 10', 10") im Wesentlichen identisch sind.

8. Ein Dauermagnetrotor nach einem der Ansprüche 1 - 7, wobei die Magnete (11, 12) an den Modulen (10, 10', 10") angeschraubt sind.

9. Ein Dauermagnetrotor nach einem der Ansprüche 1 - 8, wobei die Magnete (11, 12) an dem Basisteil (13) und/oder den Polstücken (14a, 14b) geklebt sind.

10. Ein Dauermagnetrotor nach einem der Ansprüche 1 - 9, weiterhin umfassend eine Vielzahl von Verankerungsteilen (30) zur Befestigung der Dauermagnetmodule (10, 10', 10") am Rotorkranz (32), wobei
die Dauermagnetmodule (10, 10', 10") einen Basisteil (13) umfassen, der eine untere Fläche hat, die angepasst ist, um an den inneren oder den äußeren Kreisumfang des Rotorkranzes (32) angepasst zu werden, und zwei sich axial erstreckende Seitenflächen hat, und
die zwei Seitenflächen des Basisteils (13) der Dauermagnetmodule (10, 10', 10") jeweils eine axial verlaufende Nut (16) haben, und wobei
die Form der Verankerungsteile (30) so ist, dass sie in axial verlaufende Nuten (16) von angrenzenden Dauermagnetmodulen (10, 10', 10") eingepasst werden können.

11. Ein Dauermagnetrotor nach Anspruch 10, wobei die Verankerungsteile (30) im Wesentlichen T-förmig sind.

12. Ein Dauermagnetrotor nach einem der Ansprüche 1 - 9, wobei jedes Dauermagnetmodul (10, 10', 10") eine Vielzahl von radialen Bohrungen umfasst, und wobei die Dauermagnetmodule (10, 10', 10") am Rotorkranz (32) mittels einer Vielzahl von in den radialen Bohrungen eingesetzten Bolzen (42, 71, 72) befestigt sind.

13. Ein Dauermagnetrotor nach einem der Ansprüche 1 - 12, wobei der Basisteil (13) und die Polstücke (14a, 14b) aus einem Stapel von Metallplatten (60, 61, 62) bestehen.

14. Windturbine umfassend einen Generator, der einen Generatorrotor nach einem der Ansprüche 1 - 13 hat.

Revendications

1. Un rotor à aimants permanents comprenant une couronne de rotor (32) et une pluralité de modules à aimants permanents (10, 10', 10") disposés sur la circonférence extérieure ou intérieure de la couronne de rotor (32),
les modules à aimants permanents (10, 10', 10") s'étendant généralement le long d'une direction axiale et ayant une section transversale axiale essentiellement constante, et les modules à aimants permanents comprenant
une partie de base (13) adaptée pour être fixée sur la couronne (32) du rotor de générateur, un ou plusieurs aimants permanents (11, 12), et une ou plusieurs pièces polaires (14a, 14b), dans lequel la partie de base (13) et les pièces polaires (14a, 14b) des modules à aimants permanents (10, 10', 10") sont formées de façon intégrale et les aimants (11, 12) sont incorporés dans les modules à aimants permanents (10, 10', 10"),
dans lequel chacun des aimants permanents (11, 12) a une orientation magnétique circonférentielle et une section transversale axiale essentiellement rectangulaire, et
dans lequel chacun des aimants permanents (11, 12) est incliné par rapport au plan radial (4,6) qui traverse le centre de l'aimant (11, 12) respectif
caractérisé en ce que
chacun des modules à aimants permanents (10, 10', 10") comprend un canal de refroidissement axial (15a, 15b, 15c, 15d, 17a, 17b, 19) intégré dans le respectif module à aimants permanents et s'étendant essentiellement le long de la longueur des modules (10, 10', 10").

2. Un rotor à aimants permanents selon la revendication 1, dans lequel le canal de refroidissement axial (15a, 15b, 15c, 15d, 17a, 17b, 19) est délimité par un ou plusieurs aimants (11, 12).

3. Un rotor à aimants permanents selon la revendication 1 ou 2, dans lequel les modules à aimants permanents (10, 10', 10") comprennent une première et une seconde rangée axiale d'aimants permanents (11, 12) et un canal de refroidissement central (19) disposé entre lesdites rangées première et seconde (11, 12).

4. Un rotor à aimants permanents selon la revendication 3, dans lequel le canal de refroidissement central (19) s'étend d'un bord de la première rangée d'aimants (11) à un bord de la seconde rangée d'aimants (12).

5. Un rotor à aimants permanents selon l'une quelconque des revendications 1 - 4, dans lequel un ou plusieurs des modules à aimants permanents (10, 10', 10") comprennent au moins un canal de refroidissement (15a, 15c, 15d, 17a, 19) dans la base de chacun des aimants (11, 12), et/ou au moins un canal de refroidissement (15b, 17b, 15a) dans la partie supérieure de chacun des aimants (11, 12).

6. Un rotor à aimants permanents selon la revendication 5, dans lequel un ou plus des modules à aimants permanents (10, 10', 10") comprend un canal de refroidissement (15a, 15b, 15c, 15d) dans un ou plus des quatre coins d'un ou de plusieurs aimants (11, 12).

7. Un rotor à aimants permanents selon l'une quelconque des revendications 1 - 6, dans lequel tous les modules (10, 10', 10") sont essentiellement identiques.

8. Un rotor à aimants permanents selon l'une quelconque des revendications 1 - 7, dans lequel les aimants (11, 12) sont vissés aux modules (10, 10', 10").

9. Un rotor à aimants permanents selon l'une quelconque des revendications 1 - 8, dans lequel les aimants (11, 12) sont collés à la partie de base (13) et/ou aux pièces polaires (14a, 14b).

10. Un rotor à aimants permanents selon l'une quelconque des revendications 1 - 9, comprenant en outre une pluralité d'éléments d'ancrage (30) pour fixer les modules à aimants permanents (10, 10', 10") à la couronne de rotor (32), dans lequel
les modules à aimants permanents (10, 10', 10") comprennent une partie de base (13) ayant une surface inférieure adaptée pour être ajustée à la circonférence intérieure ou extérieure de la couronne de rotor (32), et deux surfaces latérales s'étendant axialement, et
les deux surfaces latérales de la partie de base (13) des modules à aimants permanents (10, 10', 10") comprennent chacune une rainure (16) s'étendant axialement, et dans lequel
les éléments d'ancrage (30) ont une forme qui s'ajuste à des rainures (16) s'étendant axialement de modules à aimants permanents (10, 10', 10") contigus.

11. Un rotor à aimants permanents selon la revendication 10, dans lequel les éléments d'ancrage (30) ont essentiellement une forme de T.

12. Un rotor à aimants permanents selon l'une quelconque des revendications 1 - 9, dans lequel chacun des modules à aimants permanents (10, 10', 10") comprend une pluralité d'orifices radiaux, et dans lequel les modules à aimants permanents (10, 10', 10") sont fixés sur la couronne de rotor (32) moyennant une pluralité de boulons (42, 71, 72) insérés dans les orifices radiaux.

13. Un rotor à aimants permanents selon l'une quelconque des revendications 1 - 12, dans lequel la partie de base (13) et les pièces polaires (14a, 14b) sont formées par une pile de tôles métalliques (60, 61, 62).

14. Éolienne comprenant un générateur ayant un rotor de générateur selon l'une quelconque des revendications 1 - 13.

Drawing